The present invention relates to a surface treatment device, and to a surface treatment method according to preambles of the independent claims.
Surface treatment refers here to a layering process where a surface layer of a substrate is modified by allowing particles to diffuse in the substrate matrix, or where particles are deposited on the surface such that a coating is produced on the substrate. Particles used for this kind of surface treatment are typically very small, the size distribution ranging from 10 to 100 nm. Particles of this size are generally referred to as nanoparticles. Nanoparticles are generated in a particle synthesis process where precursor chemicals are exposed to a thermal reactor. In the intense heat of the thermal reactor they undergo specific thermochemical and physical reactions that lead to synthesis of desired particles.
In industrial applications, the particle synthesis process typically incorporates a source element that applies a nozzle for ejecting a combination of precursor substances for surface treatment particles, and a thermal reactor for transforming the combination of precursor substances to a directed particle flow. Typically the thermal reactor is a turbulent hydrogen-oxygen flame into which the nozzle outlet channels from one or more nozzles feed materials, either mixed together or through separate outlets.
Conventionally the surface treatment implementations have been strictly focusing to direct impact areas where the flow of nanoparticles is directed against the treated surface rectilinearly. Particle flow effects outside direct impact areas have been considered as residue and various measures have been applied to effectively eliminate these effects from industrial surface treatment processes. This conventional approach is, however quite ineffective, since a considerable amount of particles does actually not end up in the treated surface, but is removed with carrier gases away from the process atmosphere. This manifests as poor yield and added efforts for cleaning the contaminated process atmosphere.
An object of the present invention is thus to provide a method and an apparatus for implementing the method so as to overcome, or at least alleviate one or more of the above problems. The object of the invention is achieved by a surface treatment device and surface treatment method, which are characterized by what is stated in the independent claims. The preferred embodiments of the invention are disclosed in the dependent claims.
The invention is based on including in the surface treatment procedure flow control means that direct the particle flow to controllably progress from the point of direct impact along the treated surface, and deflecting means that deflect the particle flow from the surface of the planar object after the predefined distance.
An advantage of the invention is that the exposure of the treated surface with the particle flow increases and the probability of the desired surface treatment processes to take place increases. The yield from the selected precursor components improves and less precursor substances remain to be cleaned from the process atmosphere.
In the following, embodiments will be described in greater detail with reference to accompanying drawings, in which
The following embodiments are exemplary. Although the specification may refer to “an”, “one”, or “some” embodiment(s), this does not necessarily mean that each such reference is to the same embodiment(s), or that the feature only applies to a single embodiment. Single features of different embodiments may also be combined to provide further embodiments.
In the following, features of the invention will be described with a simple example of a device architecture in which various embodiments of the invention may be implemented. Only elements relevant for illustrating the embodiments are described in detail. Various implementations of surface treatment methods and devices comprise elements that are generally known to a person skilled in the art and may not be specifically described herein. Configurations of the surface treatment device may be described in operational situations where the defined device elements are mutually adjusted to provide defined flow conditions. Such adjustments of the system elements are apparent from the description and can be made through simple tests and trials by a person skilled in the art.
A surface treatment device refers here to an apparatus that generates nanoparticles and directs them to a surface to be treated. According to an embodiment of the invention, the surface treatment device comprises a source element 100 that includes a nozzle for ejecting a combination of precursor substances for surface treatment particles, and a thermal reactor for transforming the combination of precursor substances to a particle flow. The nozzle represents here an element that generates a directed flow of precursor substances and leads them into a thermal reactor. The thermal reactor represents here an element that provides a local distribution of heat such that objects traversing locations of that distribution are exposed to the heat accordingly.
In the following, an embodiment applying at least one liquid precursor substance is used as an example. However, precursor substances may be ejected in liquid, vaporous or gaseous form without deviating from the scope of protection. When one or more liquid precursors are used, the nozzle may advantageously output a premixed liquid mixture as a jet of droplets and expose this jet of droplets to a thermal reactor that transforms the jet of droplets into a directed flow of nanoparticles.
In
The nozzle 104 is also configured to combine the jet of droplets with a flow of combustible substance. A combustible substance refers here to a substance that may be ignited in defined circumstances and after ignition burns in an exothermal reaction. The combustible substance is typically a combustible gas, which in a gas flow is directed towards the jet of droplets. The combustible gas may be used as an atomizing gas of the two-fluid atomizer, or the nozzle 104 may comprise one or more separate outlets for atomizing gases and combustible gases and any other gases necessary for the flame production. In combining the jet of droplets and the combustible substance are mixed or otherwise brought into such vicinity of each other that they progress together, and after ignition of the combustible material the jet of droplets is exposed to the heat from the burning combustible material.
The nozzle 104 is further configured to ignite the exiting combustible substance. Ignition typically takes places when the combustible substance that flows out of the opening of nozzle gets exposed to the heat of an existing external flame of the combustible substance. Other means of ignition may, however, be applied without deviating from the scope of protection. The rate of flow of the combustible substance is advantageously adjusted such that the flame does not progress to the nozzle 104 or even to the immediate vicinity of the opening of the nozzle 104.
The nozzle 104 is configured to spray the jet of droplets 106 in an initial direction 110. The direction of the jet 110 refers to the average direction of propagation of the jet and the initial direction corresponds with an average direction of droplets that exit the opening of the nozzle 104. Depending on the configuration of the nozzle 104, the spray may have a defined directional pattern based on which the initial direction can typically be determined. For example, in case the droplets are sprayed as an aerosol with pressure through a circular opening, the initial direction corresponds with the direction from the center of the opening of the nozzle to the direction of the pressure field. In case the droplets are sprayed with pressure through a line-shaped opening, the initial direction corresponds with the direction from the center of the line opening of the nozzle to the direction of the pressure field.
In the heat of the flame the droplets that comprise at least one precursor material substance for nanoparticles evaporate, react, nucleate, condense, coagulate and agglomerate in a manner well known to a person skilled in the art. These processes transform the jet of droplets into a high-temperature flow of nanoparticles 108, also called as a flame. The direction of the particle flow 112 refers to the average direction of propagation of the particle flow and corresponds to the direction of the average velocity vector of the particle flow. The average velocity vector of the particle flow 112 refers to an average of velocity vectors of particles in the particle flow 112. It is evident that the direction of the average velocity vector corresponds substantially with the initial direction of the jet of droplets 110 and the speed of the average velocity vector corresponds substantially with the pressure used in spraying the jet of droplets. The particle flow 108 is typically turbulent.
In the embodiment of
The surface treatment device of the embodiment according to the invention as illustrated in
The directing means may comprise explicit flow directing elements, as well as elements that control characteristics of the flow itself. In the present embodiment, flow conditions across regions D1 and D2 may be controlled by mutual adjustments of the nozzle angle α, the flow exit velocity at the nozzle vo, and nozzle height h. For example, the directing means may be configured to adjust the velocity of the particle flow and the mutual positioning of the nozzle and the conveyor element such that during operation of the device the particle flow hits the surface of the planar object in the direction of an angle α. This angle represents the angle between the direction of propagation, i.e. the direction of the average velocity of the particle flow 112 and the surface of the treated planar object, but the angle α may also be determined from the device configuration in a straightforward manner with orientations of the nozzle 104 and the supporting surface 202. The surface of the treated planar object is parallel to the defined plane 202, here the supporting surface, and the orientation of the nozzle 104 indicates the direction of the jet 110, which again corresponds with the direction of the particle flow 112. The angle α may thus be determined on the basis of these easily measurable physical elements. The region on the surface of the planar object that the particle flow hits in the direction of an angle α is the direct impact region D2.
In the direct impact region D2, part of the particles that do not adhere immediately with the surface may bounce and drift away from the surface, and part of this particle flow may continue to progress along the surface of the planar object along the defined plane 202. The region on the surface of the planar object in which the particles are controllably directed to travel form an extended impact region D1. In this extended impact region D1 the direction of the particle flow is no more aligned to the average velocity vector of the arriving particle flow but the particle flow traverses substantially along the treated surface under influence of diffusion, thermophoresis, or the like. The particle flow thus remains in the vicinity of the surface of the planar object such that particles of the particle flow may continue to deposit on the surface or diffuse into it.
However, the extended impact region D1 should preferably not extend beyond the preferable deposition and collection zone of the particle flow. One possible limitation comes from the fact that hot, nanosized particles have a tendency to agglomerate to clusters. The size of a cluster typically has a limit after which the surface treatment process is no longer optimal. It is therefore essential that flow conditions in the path of the particle flow on the treated surface can be controlled such that the extent of the extended impact region can be kept within a preferred deposition and collection zone. The surface treatment device of
In the embodiment of
In the embodiment of
As discussed earlier, the optimal length of the deposition and collection zone that defines the optimal extent of the extended impact region is an application-specific parameter that a person skilled in the art can simply define through testing. In conditions when hydrogen/oxygen flame process is used for vertical flame deposition the nozzle distance from treated surface is typically in the order of 100 mm, particle velocity is between 100 to 300 m/s, and maximum flame temperature is in the order of 2000 degrees Celsius. The first deposition zone, i.e. the direct impact region D2 extends to some 20 mm from the point below the nozzle opening. Without any explicit flow control means, flame ends may expand to around 200 mm to either side of the direct impact region. The extended impact region D1 is thus optimally limited to regions where distances travelled by the particle flow from the direct impact region are in the order of 100-200 mm.
On many cases it is useful to tilt the nozzle such that the flame is not vertical. In the example of
Surface treatment devices according to
Vertical nozzle arrangement (α=90 degrees) provides typical conditions for liquid flame deposition, where a stagnant point occurs directly under the nozzle, and flow diverges to opposite horizontal directions around stagnant point. It is obvious that when the angle α is decreased from 90 degrees, the stagnant point moves accordingly. With a defined combination of nozzle height, angle, flow velocity and temperature a vortex may appear in the particle flow before the direct impact region D2. With linear flame arrangement this vortex is tubular in shape and easily controlled. This vortex may be used as further collection means that act as a reservoir for particles that would otherwise escape the surface treatment processes. Use of the vortex before the direct impact region D2 increases the probability of deposition or diffusion of trapped particles. By adjusting deflection means 206 in combination with the nozzle arrangement, a vortex may be formed to the extended impact region D1. In such a case, the particle flow does not travel linearly through an elongated region in the surface but circulates in a confined extended impact region. The increased interaction between the particle flow and the surface significantly increase the probability of the surface treatment reactions. Particle accumulation occurs within the vortex, and local temperature is also higher there. These together favor particle adherence to surface below the vortex thus increasing overall deposition efficiency of the process.
Also in this embodiment the far end of the extended impact region D1 may be equipped with deflecting means that deflect the particle flow away from the treated surface, as shown in
During operation the device incorporates a planar object (OBJ), the surface of which is to be treated. The device conveys the planar object through the particle flow such that the particles adhere to the surface of the planar object and implement the desired surface treatment thereto. The device may support or fix the planar object to a defined plane, and move the planar object through the particle flow. The device may, alternatively, comprise a mechanism for moving the nozzle in respect of the planar object.
When the planar object is delivered through the particle flow, the particle flow is controlled (step 54) by directing it to progress into an extended impact region D1 along the treated surface. As described with
At a defined distance from the beginning of the impact region the particle flow is deflected (step 56) from the surface of the planar object such that any adverse effects from cooled parts of the particle flow are avoided.
By means of the embodied device and method the exposure of the particle flow with the treated surface is extended and the probability of the desired surface effects to occur is significantly increased. This reduces waste and makes the process more economical. It will be obvious to a person skilled in the art that, as technology advances, the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above but may vary within the scope of the claims.
Number | Date | Country | Kind |
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20106088 | Oct 2010 | FI | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/FI2011/050921 | 10/20/2011 | WO | 00 | 9/25/2013 |